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Appendix A IDX Technologies Summary Test Report
NOTE: This document was prepared by IDX Technologies and is published as received. This
document was not edited or verified by Battelle.
A-1
March 22 2006
ETV REPORT
IDX-Technologies
1. Introduction As we have reported in many occasions in the world that we have succeeded in the
development of RIMMPA (Resonance Ionization with the Multi-Mirror system Photon
Accumulation)-TOFMS. By the development of it, we have achieved the 2 color 2 photon
resonance ionization of tetra to octa chlorinated DDs and DFs with selective soft ionization of
PCDD’s and PCDF’s isomers.
Thus, the ETV for us is to verify the technical results on RIMMPA-TOFMS.
We have adopted two countermeasures upon this current situation. The first
countermeasure is to adopt an accumulation tube as a condenser for obtaining the high
density sample gas and to use helium gas for desorbing it as carrier gas.
The second is to adopt the fixed wavelength laser to make the size compact and to realize
easy operation and mobile-ability.
What we had achieved in the laboratory was to detect the PCDD’s and PCDF’s isomers of
2,3,4,7,8-PeCDF at 410 ppq sensitivity by changing the excitation wavelength and could
detect only objective parent ion without any fragmentation.
We haven’t reached, however, the stage to detect the PCDD’s and PCDF’s isomers in the
real gas. This is one of the purposes of this ETV tests for us to establish the method and
verify the on-site and rapid analysis method in the real gas from boiler.
2. Target What we have targeted through ETV test this time was that after filtering, adsorbing and
accumulating the exhausting gas into a TENAX column, desorption of PCDD’s and PCDF’s
are carried under the specifically controlled temperature and then is loaded to
RIMMPA-TOFMS with helium carrier gas. We aimed at the two kinds of analysis, one was the
Congener analysis and the other was the Isomer analysis.
Here, we mean that the congeners analysis is to calculate the TEQ from the relation
between the sum of the total ion signals of tetra to octa chlorinated DDs and DFs and that of
the Method 23(M23). The sum of the total ion signals of tetra to octa chlorinated DDs and
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DFs congener’s ion is calculated as follows. Selecting and fixing an appropriate wavelength
of excitation laser wavelength as 310.99nm, we can get all the tetra to octa chlorinated DDs
and DFs congener’s ion signals and sum up the amount of time variation.
And the isomer analysis is to calculate the TEQ from the correlation between the total
amount of target isomer’s ion signal and that of M23 signals. Setting the excitation laser
wavelength for the target isomer and getting the isomer signal and integrating it by time, we
can get the total amount of target isomers.
3. Test circumstances Terms: Sep. 12 2005 to Sep. 22 2005
Place: U.S. Environmental Protection Agency, Research Triangle Park
Test facilities: A 2.94 MBtu/hr, 3-Pass Wetback Scotch Marine Package Boiler
manufactured by Superior Boiler Works, Inc.,
(Details are in the ETV program report)
4. Test method The schematic diagram of sampling is shown in Fig.1
The sampling steps are briefly divided into next four steps.
4.1 Adsorption
The exhausted gas flows in the Adsorption and Heat Desorption (AHD) unit from sampling
port in flue gas duct heated at 160 degree C through sampling probe heated at 200 degree C,
glass fiber filter and 5m heated sampling line (Teflon tube). At the AHD, PCDD’s and PCDF’s
in the exhausted gas are adsorbed in the 105 degree C heated TENAX column. The
exhausted gas is disposed lastly in APCS (Air Pollutant Control System) through Silica gel,
NaOH solution and pump.
4.2 Helium Substitution
To remove nitrogen, oxygen and low boiling point organic compounds that remain in
TENAX column, helium gas of 120 degree C is substituted for the gases in TENAX column of
105 degree C for 5 minutes with 3L/min.
4.3 Desorption
The column is heated up to 300 degree C after closing the entrance and exit of it. Keeping
it for 10 minutes after the temperature rises up to 300 degree C, the objective gas in helium
carrier gas is injected to RIMMPA-TOFMS at 200 degree C.
4.4 Analysis
Analysis of congeners and isomers by RIMMPA-TOFMS are carried out.
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5. Test conditions Chart 1 shows the test conditions of each day during ETV tests.
T
T
FilterOven
Glass fiberfilter withTeflon support
Sample Nozzle
Pilot Tube
Heated QuartzProbe Liner
Exhaust Gas
T
Helium Gas
RIMMPA-TOFMS
Heated Transfer Line(Stainless Steel Tube)
Flow OrificeMeter
InclineManometer
DryGasMeterPump
Cilica Gel NaOH Solution
Condenser
TENAX TA
Glass Wool
Heater Tracewith insulator
Heated Transfer Line(Teflon Tube: 5m)
3-way Valve (Some pieces)
3-way Valve (Some pieces)
Adsorption and Heat Desorption Unitincluding four condensers
Fig.1 Schematic diagram of the sampling train, adsorption and heat
desorption unit, and measurement by RIMMPA-TOFMS
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6. Test results 6.1 Congener Analysis Test Results
Chart 2 is the results of our ETV tests. The Test Number 9/19 is the result of isomer analysis
and the other all are congener analysis. The values in the chart show the signal strengths of
the dioxin congeners that RIMMPA-TOFMS detected. Although RIMMPA-TOFMS has
succeeded in congener identification of several high-chlorinated dioxins, RIMMPA-TOFMS
has not succeeded in determination of isomers due to the bad influence of impurities that
exist close to dioxins in mass numbers.
Chart 1
Ionization Laser
time [min]rate [L/min] volume [L] temp. [deg.C] flow rate [L/min] Energy [mJ] Wavelength [nm] Energy [mJ]
9/12 240 2.739 657.36 300 1 3 310.99 0.1
9/14 90 4.85 436.5 280 1 3 310.99 0.1
9/16-#1 70 17.083 1195.81 300 1 3 310.99 0.1
9/16-#2 90 16.562 1490.58 300 1 3 310.99 0.1
9/19 240 15.19 3645.6 300 1 3 315.83 0.1
9/20-#1 120 13.76 1651.2 300 0.5 3 310.19 0.5
9/20-#2 240 12.51 3002.4 300 0.5 3 310.19 0.5
9/21-#1 120 17.19 2062.8 300 0.5 3 310.19 0.5
9/21-#2 200 19.3 3860 300 0.5 3 310.19 0.5
9/22-#1 15 16.19 242.85 300 0.5 3 310.19 0.5
9/22-#2 15 16.33 244.95 200-300 0.5 3 310.19 0.5
TestNumber
Sampling DXN-Desorption Excitation Laser
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6.2 Test result details
First half
The chart 3 below shows the results from Sep. 12 to Sep. 16.
9/12 9/14 9/16-#1 9/16-#2 9/19 9/20-#1 9/20-#2 9/21-#1 9/21-#2 9/22-#1 9/22-#2
TeCDD 7.1 12.1
PeCDD 6.1 5.1
HxCDD
HpCDD
OCDD
TeCDF 1.7
PeCDF
HxCDF
HpCDF
OCDF 1.3
Blank=Not identified
Chart 2
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Sep. 12 2005
Figure 2 (Test number: 9/12) shows the mass spectrum of 270 to 500 measured by
RIMMPA-TOFMS. The ion signal was obtained by integrated value of 3 minutes
measurement. Although we recognized the PCDD’s and PCDF’s peaks, it was tough to
identify and determine PCDD’s and PCDF’s because the spectra of other impurities
overlapped the peak signals of the PCDD’s and PCDF’s. As indicated a and b in Fig.2, we
detected the spectrum of impurities that adhere to the TENAX, the mass number of which
increase by m/z 75 regularly, and the spectrum obstruct the measurements of PCDD’s and
PCDF’s. It was thought as impurity in TENAX and it disturbs the PCDD’s and PCDF’s
spectra.
Sample transfer
Adsorption
Helium substitution
Desorption
RIMMPA- TOFMS
9/12
5m Teflon tube
9/14 9/15 9/16
105 degree C
3L/min, 5min
300 degree C
310.99nm, 3mJ213nm, 0.1mJ
9/13
Pipe cleaning by solvent
New HTPD
Brand new pipe
TENAX cleaning
Cleaning and change HTPD
310.99nm, 3mJ213nm, 0.1mJ
Improvement sampling unit
change of glass wool
310.99nm, 3mJ213nm, 0.1mJ
AHD unit cleaning
Others
New He bombInsert activate charcoal between TENAX columnand He bonbe
No preheating of He gas
Results
Fig.2-12Lots of impurity
TENAX decomposition
Impossible to identify and determine
Abherence of TENAX in inside of HTPD
Adherence of TENAXin the pipe
Fig13
same as 9/12
Fig14, 15stains in the AHD unit
Higher volume of sampling rate by changing glass wool
Fig17, 18spectrum quenching of m/z320, 345
No changes in the others
Change from Helium to N2
for cleaning
Chamber baking
Congener analysis
5m Teflon tube 5m Teflon tube
Preheating of He gas 200 degree C
preheating of He gas 200 degreeC
105 degree C
3L/min, 5min
300 degree C
105 degree C
3L/min, 5min
300 degree C
Congener analysis
Congener analysis
Chart 3
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Figures 3 to 12 are the mass spectra which are expanded near PCDD’s and PCDF’s
congeners. The indicated values are relative intensity of each peak normalized by M+2 ion
signal in the case of TeCDF or M+4 ion signal in the case of OCDF. We recognized some
differences in the intensity ratio between the observed one and that estimated from
existence ratio of chlorine isotope. In the case of TeCDF, the observed ratios are 50.6/100
and 60.5/100, while the estimated ratios are 76/100 and 49/100. We assume that these
differences might be caused by the spectra overlapping.
Fig.2 Mass spectrum (Test number: 9/12)
Fig.3 TeCDF Fig.4 TeCDD
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Fig.8 HxCDD Fig.7 HxCDF
Fig.10 HpCDD Fig.9 HpCDF
Fig.6 PeCDD Fig.5 PeCDF
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Sep. 13 2005
To avoid the stains in the AHD unit, pipes and High Temperature Pulsed gas Device
(HTPD), HTPD was changed to new one. We blow off TENAX in the AHD unit by the
compressed air. And we also cleaned pipes between the AHD unit by both of compressed air
and solvent.
Sep. 14 2005
Figure 13 is the mass spectrum (mass number: 270 to 500) measured by RIMMPA-TOFMS.
The ion signals are obtained by integrated value of 3 minutes measurement. The signals of
impurity, however, did not disappear even after cleaning and changing of HTPD to new one.
It was tough to identify and determine PCDD’s and PCDF’s because the spectra of the other
impurity overlapped the peak signal of the PCDD’s and PCDF’s although we recognized the
PCDD’s and PCDF’s peaks in our results.
Fig.12 OCDD Fig.11 OCDF
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Figure 14 and 15 show the two cases of helium gas pass through the AHD unit and the
case of not passes through the unit. From these results, we realized that the inside of the
AHD unit has stained, so that we newly created another way of sampling without using the
unit. (Refer Fig.16). And we cleaned HTPD and changed the parts of the units. Also we
cleaned TENAX as well at 280 degree C for 16 hours assuming that TENAX itself has its
stain.
Fig.13 Mass spectrum (Test number: 9/14)
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Fig.14 through the AHD unit Fig.15 not going through the AHD unit
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Sep. 16 2005
We changed the glass wool to raise the sampling rate, and changed a helium cylinder to a
new one as well. And we inserted the activated charcoal filter between helium cylinder and
TENAX column to avoid impurity in the helium gas.
T
T
FilterOven
Glass fiberfilter withTeflon support
Sample Nozzle
Pilot Tube
Heated QuartzProbe Liner
Exhaust Gas
T
Helium Gas
RIMMPA-TOFMS
Heated Transfer Line(Stainless Steel Tube)
Flow OrificeMeter
InclineManometer
DryGasMeterPump
Cilica Gel NaOH Solution
Condenser
TENAX TA
Glass Wool
Heater Tracewith insulator
Heated Transfer Line(Teflon Tube: 5m)
3-way Valve
3-way Valve
Fig.16 Schematic diagram of the sampling train, adsorption and heat
desorption by single condenser, and measurement by RIMMPA-TOFMS
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Figure 17(Test number: 9/16-#1), Fig.18 (Test number: 9/16-#2) are the mass spectra
(mass number: 270 to 500) measured by RIMMPA-TOFMS and the mass spectra are
obtained by integrated value of 3 minutes measurement. If we compare with the Fig.14, the
ion signal of mass number 320 and 345 are decreased. However, we could not identify and
determine the PCDD’s and PCDF’s due to the peaks of impurity.
We changed the cleaning solvents from helium to nitrogen and cleaned HTPD again at 200
degree C for a day. Baking in the chamber was also done for a day. Another way that we did
was to change to a 3/4 inch tube that doesn’t require seal tape because we assumed that the
exhausted gas from seal tape might cause the noise in the spectra of PCDD’s and PCDF’s.
Second half
The chart 4 below shows the summary of the results of sep. 19 thru Sep.22
Fig.17 Mass spectrum(Test number:9/16-#1) Fig.18 Mass spectrum(Test number: 9/16-#2)
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Sep.19 2005
Though many kinds of material are ionized because we use the shorter wavelength of the
excitation laser in the congener analysis, the only selected isomers would be ionized in the
isomer analysis because the longer wavelength of excitation laser is applied.
Figure 19 (Test number: 9/19) is the mass spectrum (mass number: 270 to 500) when we
carried out the isomer analysis of 2,3,4,7,8-PeCDF. The ion signal is integrated value for 3
minutes measurement. The peak signals of mass number 395, 410 quenched, 470 and 490
decreased and peak signal of mass number 362 was increased. These materials are
resonantly ionized by the excitation laser wavelength of 2,3,4,7,8-PeCDF.
Figure 20 is the mass spectrum near the 2,3,4,7,8-PeCDF. Although there exist the peak
signals in the m/z=338, 340 and 342, we could not identify the 2,3,4,7,8-PeCDF isomer
because the ionization intensity is different from the ionization intensity ratio that can be
estimated by the isotope existence ratio.
Chart 4
Sample transfer
Adsorption
Helium substitution
Desorption
RIMMPA- TOFMS
9/19
5m Teflon tube
9/21 9/22
105 degree C
3L/min, 5min
300 degree C
315.83nm, 3mJ213nm, 0.1mJ
9/20
Others
Results
Fig.19
Congener analysis
5m Teflon tube
105 degree C
3L/min, 5min
300 degree C
310.19nm, 3mJ213nm, 0.5mJ
310.19nm, 3mJ213nm, 0.5mJ
310.19nm, 3mJ213nm, 0.5mJ
Isomer analysis(2,3,4,7,8-PeCDF)
Congener analysis Congener analysisNo preheating of He gas
Change the 3/4 inch tube
Spectrum quenching of m/z395, 410
Spectrum decreasing of m/z470, 490
Fig.20Detect the peak signals in the m/z=338,340 and 342
2,3,4,7,8-PeCDF isomer is imposible to identify
Change to improve the sensitivity
105 degree C
3L/min, 5min
300 degree C
No preheating of He gas No preheating of He gas No preheating of He gas
Leak check of sampling line
Doubled the volume the second sampling of first volume
105 degree C
3L/min, 5min
300 degree C
Set TENAX column directly after the filter
Set TENAX column directly after the filter
Fig.21-32
TeCDD, PeCDD is posible to identify
No detection of HpCDD,OCDF,OCDD
Other congeners are imposible to identify
Fig.34-45
Same as previous day
There is a possibility TENAX was broken through due to the toomuch sampling amount
m/z278 signal increasedFig.46-56
Congeners are imposible to identify
Detection of mass spectrumm/z260, 262
Fig.57The flow rate 0.5 to 3 L/minthe ion signals increased
No use No use
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Sep.20 2005
We changed from isomer analysis to congener analysis because we could not identify
2,3,4,7,8-PeCDF in isomer analysis. We did leak check of sampling port before tests. To rise
up the sensitivity, we changed the excitation laser wavelength to 310.19nm and ionization
laser energy to 0.5 mJ because we thought the PCDD’s and PCDF’s density was too low to
detect. We tested whether the peak signals become doubled when we sample the double
volume as first sampling volume.
Figure 21 (Test number: 9/20-#1), Fig.22 (Test number: 9/20-#2) are the mass spectra
(mass number: 270 to 500) measured by RIMMPA-TOFMS and the mass spectra are
obtained by integrated value of 3 minutes measurement. The second sampling volume was
double of the first one, however, the signals in the second sampling were lower than the first
one.
Fig.19 Mass spectrum (Test number: 9/19) Fig.20 2,3,4,7,8-PeCDF
Fig.21 Mass spectrum (Test number:9/20-#1) Fig.22 Mass spectrum(Test number:9/20-#2)
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Figures 23 to 32 are the mass spectra which are expanded the near parent-ion spectrum of
the tetra to octa chlorinated DDs and DFs. The indicated values are relative intensity of each
peak normalized by M+2 ion signal in the case of TeCDD, PeCDD. We recognized some
differences in the intensity ratio between the observed one and that estimated from
existence ratio of chlorine isotope. In the case of TeCDD, the observed ratios are 71.2/100
and 57.6/100, while the estimated ratios are 77.4/100 and 48.7/100. But no detection was
made on HpCDD, OCDF and OCDD or of the other congeners.
Fig.23 TeCDF Fig.24 TeCDD
Fig.25 PeCDF Fig.26 PeCDD
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Fig.31 OCDF Fig.32 OCDD
Fig.27 HxCDF Fig.28 HxCDD
Fig.30 HpCDD Fig.29 HpCDF
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Sep.21 2005
Knowing the fact that PCDD’s and PCDF’s are decreased to 1/2 during the gas moves
30cm in a 1/4 inch size Teflon tube, and that if a Teflon tube is heated at 200 degrees C, out
gas will occur and PCDD’s and PCDF’s will be denatured, the 5m heated sampling line
(Teflon tube) prepared before the experiment was removed. So the TENAX column was set
directly after the filter of filter oven (Fig.33). After sampling, the temperature of the TENAX
column was cooled down from 105 degree C and took it out from Filter Oven. And bringing it
to the site of RIMMPA-TOFMS and going into the steps of helium substitution, desorption
and analysis were curried out.
Figure 34 (Test number: 9/21-#1), Fig.35 (Test number: 9/21-#2) are the mass spectra
(mass number: 270 to 500) measured by RIMMPA-TOFMS and the mass spectra are
obtained by integrated value of 3 minutes measurement. The total trend of the results of
no-use of Teflon tube was not different from the case of use of it. The second sampling
volume was doubled as the previous day and the signals of impurity were decreased on this
day. We decided it had break through since there are too many amounts of samplings.
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T
T
T
Flow OrificeMeter
InclineManometer
DryGasMeterPump
Cilica Gel NaOH Solution
Condenser
TENAX TA
Glass Wool
Heater Tracewith insulator
FilterOven
Glass fiberfilter withTeflon support
Sample Nozzle
Pilot Tube
Heated QuartzProbe Liner
T
Helium Gas
RIMMPA-TOFMS
Heated Transfer Line(Stainless Steel Tube)
Exhaust Gas
Hand carry
Fig.33 Schematic diagram of the sampling train, with single condenser,
connected to filter directly, and measurement by RIMMPA-TOFMS
Fig.34 Mass spectrum (9/21-#1) Fig.35 Mass spectrum (9/21-#2)
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Figures 36 to 45 are the mass spectra which are expanded near parent-ion spectrum of the
tetra to octa chlorinated DDs and DFs. The indicated values are relative intensity of each
peak normalized by M+2 ion signal in the case of TeCDD, PeCDD. We recognized some
differences in the intensity ratio between the observed one and that estimated from
existence ratio of chlorine isotope. In the case of TeCDD the observed ratios are 67.2/100
and 38.8/100, while the estimated ratios are 77.4/100 and 48.7/100.
But the other congeners were impossible to identify.
Fig.36 TeCDF Fig.37 TeCDD
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Fig.38 PeCDF Fig.39 PeCDD
Fig.40 HxCDF Fig.41 HxCDD
Fig.42 HpCDF Fig.43 HpCDD
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Sep.22 2005
To avoid the break through, we reduced the TENAX volume to 1 g and for the second
sampling 2.5g and the volume of sampling itself were reduced.
Figure 46(Test number: 9/22-#1) is the mass spectrum (mass number: 270 to 500)
measured by RIMMPA-TOFMS and the mass spectrum was obtained by integrated value of
3 minute measurements. Although the sampling volume was 1/8 of the previous day, the ion
signals of mass number 278 and 280 were increased, and the other signals are decreased.
We also measured the lower mass region from 250 to 270 and we recognized the spectra in
mass number 260 and 262. It was assumed that the PAH or chlorinated PAH from boiler.
Fig. 45 OCDD Fig.44 OCDF
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Figures 47 to 56 are the mass spectra which are expanded near parent-ion spectrum of the
tetra to octa chlorinated DDs and DFs. The signals of impurity were decreased because the
sampling volume was decreased and also the tetra to octa chlorinated DDs and DFs mass
signals are decreased and we could not identify it nor determinate it.
Fig.46 Mass spectrum (Test number:9/22-#1)
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Fig.47 TeCDF Fig.48 TeCDD
Fig.49 PeCDF Fig.50 PeCDD
Fig.51 HxCDF Fig.52 HxCDD
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It is because the some absorbed materials in TENAX were remained due to the low flow
rate of helium gas.
Figure 57 is the mass spectrum obtained by RIMMPA-TOMS in the case of increasing
helium flow rate to 3 L/min after the measurement end of Test number: 9/22-#2. Comparing
to the data of 0.5 L/min, the ion signals increased. We thought the sample remained in the
TENAX column not being pushed out.
Fig.53 HpCDF Fig.54 HpCDD
Fig.55 OCDF Fig.56 OCDD
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7. Conclusion
What we have performed this time through the test is
1. We straggled for adjusting the Adsorption and Heated Desorption.
2. It has taken us much time to get rid of unexpected occurrence of PAH & Poly-Chlorinated
PAH that caused from Naphthalene Cu to generate Dioxin.
3. This PC-PAH causes the damages to break the congener ratio which is essential to
identification of PCDDs/PCDFs because they overlap with those of PCDDs/PCDFs.
Even under this situation, we tried two types of analysis of congeners and isomers.
In the congener analysis, the peaks detected in the vicinity of mass of TeCDF, TeCDD,
PeCDD, and OCDF were able to be identified. However, it was difficult to identify other
congeners because PAH and chlorinated PAH contained in exhaust gas came in succession
with spectra of PCDD’s and PCDF’s. With regard to the results of PAH or chlorinated PAH
that we have got in the experiment, are shown in chart 5.
In the case of isomer analysis 2,3,4,7,8-PeCDF, we detected mass peaks in the mass
number 338, 340 and 342. It was tough however, to identify and to measure because the
intensity ratio of the isotopes 338, 340, 342 observed is different from the signal calculated
by the existence ratio. It was not possible to identify the isotope signals of 2, 3, 4, 7, 8- PeCDF,
because the mass spectra of impurities (PAH and chlorinated PAH etc.) that existed in the
mass neighborhood of 2, 3, 4, 7, 8- PeCDF came in succession, and detection was
obstructed.
Fig.57 Mass spectrum
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Through this ETV test this time, we realized that the toughness in the real gas but at the
same time we learned many things and eventually we have to the stage to convince that we
are very close to be able to detect the isomer analysis in real gas in the very near future.
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Chart 5
m/z260 C18H9Cl C18H12O2Cl4262 C18H11Cl C18H14O2
278 C18H12OCl C22H14
280 C22H16
284 C12H6S2Cl2 C12H6O2SCl2286 C20H11Cl
292 C23H16
294 C18H8Cl2 C12H10Cl4296 C18H10Cl2 C18H13O2Cl
298 C12H7O3S2Cl C18H15O2Cl
304 C20H16O3 C24H16 C18H24O4
312 C18H10OCl2314 C14H12O2SCl2318 C21H15OCl C12H5S2Cl3 C12H5SO2Cl3320 C20H10Cl2328 C22H13OCl
334 C24H11Cl
336 C20H10OCl2344 C18H10O3Cl2 C22H10Cl2 C18H7OCl3346 C18H9OCl3 C22H12Cl2360 C22H10OCl2362 C28H26 C26H15Cl C26H18O2
368 C24H10Cl2380 C18H8OCl4384 C24H10OCl2394 C26H12Cl2 C26H15O2Cl
396 C26H14Cl2 C26H17O2Cl
410 C26H12OCl2 C26H14OCl4412 C26H14OCl2
Compound